CN215782923U - Silicone oil feeding machine with emulsifying function - Google Patents

Abstract

The utility model provides a silicone oil feeding machine with an emulsifying function, which comprises a U-shaped support, a reinforcing steel plate, a limiting vertical cylinder, a sliding hole, a threaded lifting column, a lifting platform, a speed reducing motor, a controller, a control switch, a stirring motor, a gear shaft, a stirring suction pipe structure, a negative pressure pump, a first hose, a second hose, a detachable sealing cover structure and a rotary joint, wherein the reinforcing steel plate is welded between the U-shaped support and the limiting vertical cylinder, and the limiting vertical cylinder is welded on the left side of the upper end of the U-shaped support; the sliding holes are respectively formed in the front side and the rear side of the interior of the limiting vertical cylinder, and the lifting platform is inserted into the sliding holes; the thread lifting column is arranged in the limiting vertical cylinder through a bearing. The utility model has the beneficial effects that: through the setting of stirring suction tube structure, the work of emulsification stirring is realized in the supplementary rotation.

Description

Silicone oil feeding machine with emulsifying function

Technical Field

The utility model belongs to the technical field of silicone oil feeding, and particularly relates to a silicone oil feeding machine with an emulsifying function.

Background

Emulsified silicone oil, also known as silky element, the chemical property is stable, and is non-volatile, and is difficult to burn, does not have corrosivity to the metal, also is difficult for gelling in arranging the air in for a long time, in realizing the emulsification course of working to silicone oil, operates in carrying the emulsion machine through the material loading machine is convenient quick carries out the material loading work through the material loading machine more at the material loading in-process to quick supplementary emulsification work.

However, the existing silicone oil feeding machine also has the problems that the stirring and emulsification of silicone oil are inconvenient to assist and the fixed sealing at the joint is inconvenient.

Therefore, the utility model of the silicone oil feeding machine with the emulsifying function is very necessary.

SUMMERY OF THE UTILITY MODEL

In order to solve the technical problems, the utility model provides a silicone oil feeding machine with an emulsifying function, which aims to solve the problems that the existing silicone oil feeding machine is inconvenient to assist silicone oil stirring and emulsification and a joint is inconvenient to fix and seal. A silicone oil feeding machine with an emulsifying function comprises a U-shaped support, a reinforcing steel plate, a limiting vertical cylinder, a sliding hole, a threaded lifting column, a lifting platform, a speed reducing motor, a controller, a control switch, a stirring motor, a gear shaft, a stirring suction pipe structure, a negative pressure pump, a first hose, a second hose, a detachable sealing cover structure and a rotary joint, wherein the reinforcing steel plate is welded between the U-shaped support and the limiting vertical cylinder, and the limiting vertical cylinder is welded on the left side of the upper end of the U-shaped support; the sliding holes are respectively formed in the front side and the rear side of the interior of the limiting vertical cylinder, and the lifting platform is inserted into the sliding holes; the thread lifting column is arranged in the limiting vertical cylinder through a bearing; the lifting platform is sleeved on the outer wall of the limiting vertical cylinder, and the left side in the lifting platform is in threaded connection with the threaded lifting column; the speed reducing motor is mounted at the upper end of the limiting vertical cylinder through a bolt; the controller bolt is arranged on the middle left side of the front part of the upper surface of the U-shaped support, and a control switch is embedded at the front end of the controller; the stirring motor is arranged on the middle right side of the lower end of the lifting platform through a bolt; the gear shaft is embedded on an output shaft of the stirring motor; the stirring material suction pipe structure is arranged on the right side in the lifting platform; the negative pressure pump bolt is arranged on the right side of the upper surface of the lifting platform; one end of the first hose is embedded at the right end of the negative pressure pump, and the other end of the first hose is structurally connected with the detachable sealing cover; one end of the second hose is embedded in the upper end of the rotary joint, and the other end of the second hose is structurally connected with the detachable sealing cover; the rotary joint is structurally connected with the stirring material suction pipe; the detachable sealing cover structure comprises a connecting disc, a fixing plate, a feeding head, an air suction head, an annular air bag, an inflation valve and a connecting side plate structure, wherein the fixing plate is welded on the upper part and the lower part of the left end of the connecting disc respectively; the feed head and the suction head are respectively embedded on the left side inside the connecting disc; the annular air bag is glued on the outer side of the right surface of the connecting disc, and an inflation valve is embedded in the upper part of the front end of the annular air bag; the connecting side plate structures are respectively arranged at the upper end and the lower end of the connecting plate.

Preferably, the connecting side plate structure comprises a transverse supporting plate, a threaded vertical rod, an operating cross rod, a sleeving seat, a connecting groove and a sealing disc, wherein the transverse supporting plate is welded at the upper end and the lower end of the connecting disc respectively, and the threaded vertical rod is connected to the right side thread in the transverse supporting plate; one end of the threaded vertical rod is provided with an operating cross rod through a bolt, and the other end of the threaded vertical rod is inserted into the connecting groove; the inside upside of cup joint the seat seted up the spread groove, simultaneously at the lower part bolted mounting of spread groove inner wall sealed dish.

Preferably, the stirring and material sucking pipe structure comprises a vertical suction pipe, a transmission gear, a connecting ring, a positioning plate, a movable plate and a clamping bolt, wherein the vertical suction pipe is arranged on the middle right side in the lifting platform through a bearing; the transmission gear is embedded at the upper part of the outer wall of the vertical suction pipe; the connecting ring is welded at the lower part of the outer wall of the vertical suction pipe; the positioning plates are respectively welded on the left side and the right side of the outer wall of the connecting ring, and the movable plate is sleeved on the outer sides of the positioning plates; the clamping bolt is in threaded connection with the inner side of the movable plate.

Preferably, the upper end of the limiting vertical cylinder is provided with a steel disc, the steel disc movably supports the threaded lifting column, and the upper surface of the steel disc supports the speed reduction motor.

Preferably, the inner side of the annular air bag is respectively provided with a feeding head and an air suction head, and the front end part of the annular air bag is communicated with an inflation valve.

Preferably, the left end of the feeding head is inlaid with a second hose, and the left end of the suction head is inlaid with a first hose.

Preferably, the connecting groove in the sleeving seat is in a convex shape, and the lower side of the connecting groove is sealed through a sealing disc.

Preferably, the lower end of the threaded vertical rod is provided with a steel disc, the threaded vertical rod is limited in the connecting groove through the steel disc, and the threaded vertical rod and the operation cross rod are assembled to form a T shape.

Preferably, the transmission gear on the outer wall of the vertical suction pipe is meshed with the gear shaft.

Preferably, the positioning plate is matched with the movable plate, and the joint is fixed through a clamping bolt.

Compared with the prior art, the utility model has the beneficial effects that:

in the utility model, the arrangement of the connecting disc and the fixing plate is matched with other structures for assembly and subsequent reinforcement.

According to the utility model, the arrangement of the feeding head and the suction head can realize negative pressure suction and material injection.

In the utility model, the arrangement of the annular air bag and the inflation valve realizes sealing of the connection position of the connection disc.

In the utility model, the arrangement of the transverse support plate and the threaded vertical rod is matched with the movable support of the threaded vertical rod for operation and use.

In the utility model, the sleeve joint seat and the threaded vertical rod are arranged to clamp and fix the joint of the connecting disc.

In the utility model, the arrangement of the connecting groove and the sealing disc enables the sleeve joint seat to be movably connected with the threaded vertical rod.

In the utility model, the vertical suction pipe, the transmission gear, the stirring motor and the gear shaft are arranged to assist in rotation to realize the emulsification stirring work.

According to the utility model, the positioning plate, the movable plate and the clamping bolt are arranged, so that the container can be conveniently adjusted and matched with different containers for use.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural view of a detachable sealing cover structure according to the present invention;

FIG. 3 is a schematic structural view of the connecting side panel structure of the present invention;

FIG. 4 is a schematic structural view of a stirring straw structure of the present invention;

fig. 5 is a schematic electrical wiring diagram of the present invention.

In the figure:

1. a U-shaped support; 2. reinforcing the steel plate; 3. limiting the vertical cylinder; 4. a slide hole; 5. a threaded lifting column; 6. a lifting platform; 7. a reduction motor; 8. a controller; 9. a control switch; 10. a stirring motor; 11. a gear shaft; 12. a stirring suction pipe structure; 121. a vertical straw; 122. a transmission gear; 123. a connecting ring; 124. positioning a plate; 125. a movable plate; 126. clamping the bolt; 13. a negative pressure pump; 14. a first hose; 15. a second hose; 16. disassembling and assembling the sealing cover structure; 161. a connecting disc; 162. a fixing plate; 163. a feed head; 164. an air suction head; 165. an annular air bag; 166. an inflation valve; 167. connecting the side plate structures; 1671. a transverse support plate; 1672. a threaded vertical rod; 1673. operating the cross bar; 1674. a socket joint seat; 1675. connecting grooves; 1676. sealing the disc; 17. a rotary joint.

Detailed Description

The utility model is further described below with reference to the accompanying drawings:

example (b):

as shown in the attached figure 1, a silicone oil feeding machine with an emulsifying function comprises a U-shaped support 1, a reinforced steel plate 2, a limiting vertical cylinder 3, a sliding hole 4, a threaded lifting column 5, a lifting platform 6, a speed reducing motor 7, a controller 8, a control switch 9, a stirring motor 10, a gear shaft 11, a stirring material sucking pipe structure 12, a negative pressure pump 13, a first hose 14, a second hose 15, a detachable sealing cover structure 16 and a rotary joint 17, wherein the reinforced steel plate 2 is welded between the U-shaped support 1 and the limiting vertical cylinder 3, and the limiting vertical cylinder 3 is welded on the left side of the upper end of the U-shaped support 1; the sliding holes 4 are respectively arranged at the front side and the rear side inside the limiting vertical cylinder 3, and the lifting platform 6 is inserted into the sliding holes 4; the threaded lifting column 5 is arranged inside the limiting vertical cylinder 3 through a bearing; the lifting platform 6 is sleeved on the outer wall of the limiting vertical cylinder 3, and the left side in the lifting platform 6 is in threaded connection with the threaded lifting column 5; the speed reducing motor 7 is mounted at the upper end of the limiting vertical cylinder 3 through bolts; the reduction motor 7 is driven to enable the threaded lifting column 5 to rotate so as to be matched with the lifting platform 6 to adjust the lifting on the outer wall of the limiting vertical cylinder 3; the controller 8 is mounted on the middle left side of the front part of the upper surface of the U-shaped support 1 through a bolt, and a control switch 9 is embedded at the front end of the controller 8; the stirring motor 10 is arranged on the middle right side of the lower end of the lifting platform 6 through bolts; the gear shaft 11 is embedded on the output shaft of the stirring motor 10; the stirring suction pipe structure 12 is arranged on the right side inside the lifting platform 6; the negative pressure pump 13 is mounted on the right side of the upper surface of the lifting platform 6 through bolts; one end of the first hose 14 is embedded at the right end of the negative pressure pump 13, and the other end of the first hose is connected with the detachable sealing cover structure 16; one end of the second hose 15 is embedded in the upper end of the rotary joint 17, and the other end of the second hose is connected with the detachable sealing cover structure 16; the rotary joint 17 is connected with the stirring material suction pipe structure 12.

As shown in fig. 2, in the above embodiment, specifically, the detachable sealing cover structure 16 includes a connecting plate 161, a fixing plate 162, a feeding head 163, an air suction head 164, an annular air bag 165, an inflation valve 166 and a connecting side plate structure 167, wherein the fixing plate 162 is welded to the upper and lower parts of the left end of the connecting plate 161; the feeding head 163 and the air suction head 164 are respectively embedded in the left side of the inner part of the connecting disc 161, and meanwhile, the second hose 15 is embedded in the left end of the feeding head 163 and the first hose 14 is embedded in the left end of the air suction head 164; the driving negative pressure pump 13 is matched with the first hose 14 and the air suction head 164 to generate negative pressure inside the emulsification reaction kettle, and is matched with the negative pressure vertical suction pipe 121 to suck materials in the material container to be injected into the emulsification reaction kettle through the second hose 15 and the feeding head 163 to complete the feeding work; the annular air bag 165 is glued on the outer side of the right surface of the connecting disc 161, and an inflation valve 166 is embedded in the upper part of the front end of the annular air bag 165; the annular air bag 165 is inflated through the inflation valve 166 to seal the connection position of the connection disc 161 and the material injection pipe; the connecting side plate structures 167 are respectively installed at the upper and lower ends of the connecting plate 161.

As shown in fig. 3, in the above embodiment, specifically, the connecting side plate structure 167 includes a transverse support plate 1671, a threaded vertical rod 1672, an operating cross rod 1673, a sleeve seat 1674, a connecting groove 1675 and a sealing disc 1676, the transverse support plate 1671 is welded at the upper end and the lower end of the connecting disc 161, and the threaded vertical rod 1672 is screwed to the right side inside the transverse support plate 1671; the transverse support plate 1671 is sleeved on the outer side of the material injection pipe, and then the cross rod 1673 is manually rotated to drive the threaded vertical rod 1672 to rotate; an operating cross rod 1673 is arranged at one end of the threaded vertical rod 1672 through a bolt, and the other end of the threaded vertical rod 1672 is inserted into the connecting groove 1675; the rotating thread vertical rod 1672 drives the sleeve joint seat 1674 to be clamped on the outer wall of the material injection pipe to be fixed; connecting groove 1675 has been seted up to the inside upside of cup joint seat 1674, sealed dish 1676 is installed to the lower part bolt at connecting groove 1675 inner wall simultaneously.

As shown in fig. 4, in the above embodiment, specifically, the stirring and material sucking pipe structure 12 includes a vertical sucking pipe 121, a transmission gear 122, a connection ring 123, a positioning plate 124, a movable plate 125 and a clamping bolt 126, and the vertical sucking pipe 121 is installed at the middle right side inside the lifting platform 6 through a bearing; the transmission gear 122 is embedded at the upper part of the outer wall of the vertical suction pipe 121; the stirring motor 10 is driven to drive the gear shaft 11 to rotate, and the rotating gear shaft 11 is matched with the transmission gear 122 to enable the vertical suction pipe 121, the positioning plate 124 and the movable plate 125 to rotate for stirring and emulsifying; the connecting ring 123 is welded at the lower part of the outer wall of the vertical suction pipe 121; the positioning plate 124 is respectively welded at the left side and the right side of the outer wall of the connecting ring 123, and the movable plate 125 is sleeved at the outer side of the positioning plate 124; the manual movable plate 125 is adjusted to a proper position on the outer wall of the positioning plate 124, and then the clamping bolt 126 inside the movable plate 125 is tightened to be fixed; the clamping bolt 126 is screwed to the inner side of the movable plate 125.

In the above embodiment, the speed reduction motor 7 is a 5IK60RGN-CF motor.

In the above embodiment, specifically, the controller 8 uses a PLC of model FX 2N-48.

In the above embodiment, the stirring motor 10 is a 5IK60RGN-CF motor.

In the above embodiment, specifically, the negative pressure pump 13 is an AP-2000H type negative pressure pump.

In the above embodiment, specifically, the control switch 9 is electrically connected to the controller 8, the decelerating motor 7 is electrically connected to the controller 8, the stirring motor 10 is electrically connected to the controller 8, and the negative pressure pump 13 is electrically connected to the controller 8.

Principle of operation

The working principle of the utility model is as follows: the container for storing materials is placed on the inner side of the U-shaped support 1, then the reduction motor 7 is driven to enable the threaded lifting column 5 to rotate so as to be matched with the lifting platform 6 to lift and adjust on the outer wall of the limiting vertical cylinder 3, the vertical suction pipe 121, the positioning plate 124 and the movable plate 125 are inserted into the container in the lifting process, then the stirring motor 10 is driven to drive the gear shaft 11 to rotate, the rotating gear shaft 11 is matched with the transmission gear 122 to enable the vertical suction pipe 121, the positioning plate 124 and the movable plate 125 to rotate for stirring and emulsifying, the connecting disc 161 is tightly attached to the material injection pipe of the emulsion reaction kettle in the primary treatment process, meanwhile, the transverse supporting plate 1671 is sleeved on the outer side of the material injection pipe, then the transverse rod 1673 is manually rotated to operate to drive the threaded vertical rod 1672 to rotate, the rotating threaded vertical rod 1672 drives the sleeving seat 1674 to be clamped on the outer wall of the material injection pipe to be fixed, after the connecting point of the connecting disc 161 and the material injection pipe is inflated and sealed through the annular air bag 165 through the inflation valve 166, finally, the negative pressure pump 13 is driven to cooperate with the first hose 14 and the suction head 164 to generate negative pressure inside the emulsification reactor, and simultaneously cooperate with the negative pressure vertical suction pipe 121 to suck the material in the material container to be injected into the emulsification reactor through the second hose 15 and the feeding head 163 to complete the feeding operation.

The technical solutions of the present invention or similar technical solutions designed by those skilled in the art based on the teachings of the technical solutions of the present invention are all within the scope of the present invention.

Claims (8)

1. The silicone oil feeding machine with the emulsifying function is characterized by comprising a U-shaped support (1), a reinforcing steel plate (2), a limiting vertical cylinder (3), a sliding hole (4), a threaded lifting column (5), a lifting platform (6), a speed reduction motor (7), a controller (8), a control switch (9), a stirring motor (10), a gear shaft (11), a stirring suction pipe structure (12), a negative pressure pump (13), a first hose (14), a second hose (15), a dismounting sealing cover structure (16) and a rotary joint (17), wherein the reinforcing steel plate (2) is welded between the U-shaped support (1) and the limiting vertical cylinder (3), and the limiting vertical cylinder (3) is welded on the left side of the U-shaped support (1); the sliding holes (4) are respectively arranged at the front side and the rear side in the limiting vertical cylinder (3), and a lifting platform (6) is inserted in the sliding holes (4); the thread lifting column (5) is arranged in the limiting vertical cylinder (3) through a bearing; the lifting platform (6) is sleeved on the outer wall of the limiting vertical cylinder (3), and the left side in the lifting platform (6) is in threaded connection with the threaded lifting column (5); the speed reducing motor (7) is mounted at the upper end of the limiting vertical cylinder (3) through bolts; the controller (8) is installed on the middle left side of the front part of the upper surface of the U-shaped support (1) through a bolt, and a control switch (9) is embedded at the front end of the controller (8); the stirring motor (10) is arranged on the middle right side of the lower end of the lifting platform (6) through bolts; the gear shaft (11) is embedded on an output shaft of the stirring motor (10); the stirring and material sucking pipe structure (12) is arranged on the right side in the lifting platform (6); the negative pressure pump (13) is arranged on the right side of the upper surface of the lifting platform (6) through bolts; one end of the first hose (14) is embedded at the right end of the negative pressure pump (13), and the other end of the first hose is connected with the detachable sealing cover structure (16); one end of the second hose (15) is embedded at the upper end of the rotary joint (17), and the other end of the second hose is connected with the detachable sealing cover structure (16); the rotary joint (17) is connected with the stirring material suction pipe structure (12); the detachable sealing cover structure (16) comprises a connecting disc (161), a fixing plate (162), a feeding head (163), an air suction head (164), an annular air bag (165), an inflation valve (166) and a connecting side plate structure (167), wherein the fixing plate (162) is welded to the upper part and the lower part of the left end of the connecting disc (161); the feed head (163) and the suction head (164) are respectively embedded in the left side of the inner part of the connecting disc (161); the annular air bag (165) is glued on the outer side of the right surface of the connecting disc (161), and an inflation valve (166) is embedded in the upper part of the front end of the annular air bag (165); the connecting side plate structures (167) are respectively arranged at the upper end and the lower end of the connecting plate (161).

2. The silicone oil feeding machine with the emulsifying function as claimed in claim 1, wherein the connecting side plate structure (167) comprises a transverse supporting plate (1671), a threaded vertical rod (1672), an operating cross rod (1673), a sleeving seat (1674), a connecting groove (1675) and a sealing disc (1676), the transverse supporting plate (1671) is welded at the upper end and the lower end of the connecting disc (161) respectively, and the threaded vertical rod (1672) is connected to the right side of the inside of the transverse supporting plate (1671) in a threaded manner; one end of the threaded vertical rod (1672) is provided with an operating cross rod (1673) by a bolt, and the other end of the threaded vertical rod is inserted into the connecting groove (1675); connecting groove (1675) have been seted up to the inside upside of cup joint seat (1674), sealed dish (1676) are installed to the lower part bolt at connecting groove (1675) inner wall simultaneously.

3. The silicone oil feeding machine with the emulsifying function as claimed in claim 1, wherein a steel disc is arranged at the upper end of the limiting vertical cylinder (3), a threaded lifting column (5) is movably supported in the steel disc, a speed reducing motor (7) is supported on the upper surface of the steel disc, a second hose (15) is embedded at the left end of the feeding head (163), and a first hose (14) is embedded at the left end of the air suction head (164).

4. The silicone oil feeding machine with emulsifying function as claimed in claim 1, wherein the inner side of the annular air bag (165) is respectively provided with a feeding head (163) and a suction head (164), and the front end part of the annular air bag (165) is communicated with an inflation valve (166).

5. The silicone oil feeder with the emulsifying function as claimed in claim 2, wherein a steel disc is arranged at the lower end of the thread vertical rod (1672), the thread vertical rod (1672) is limited in the connecting groove (1675) through the steel disc, and the thread vertical rod (1672) is assembled with the operating cross rod (1673) to form a T shape.

6. The silicone oil feeder with emulsifying function as claimed in claim 2, wherein the connecting groove (1675) inside the sleeve joint seat (1674) is arranged in a convex shape, and the underside of the connecting groove (1675) is sealed by the sealing disc (1676).

7. The silicone oil feeding machine with the emulsifying function as claimed in claim 1, wherein the stirring and suction pipe structure (12) comprises a vertical suction pipe (121), a transmission gear (122), a connecting ring (123), a positioning plate (124), a movable plate (125) and a clamping bolt (126), and the vertical suction pipe (121) is mounted on the middle right side inside the lifting platform (6) through a bearing; the transmission gear (122) is embedded at the upper part of the outer wall of the vertical suction pipe (121); the connecting ring (123) is welded at the lower part of the outer wall of the vertical suction pipe (121); the positioning plates (124) are respectively welded at the left side and the right side of the outer wall of the connecting ring (123), and the outer sides of the positioning plates (124) are sleeved with the movable plates (125); the clamping bolt (126) is in threaded connection with the inner side of the movable plate (125).

8. The silicone oil feeder with emulsifying function as claimed in claim 7, wherein the transmission gear (122) on the outer wall of the vertical suction pipe (121) is engaged with the gear shaft (11), the positioning plate (124) is adapted to the movable plate (125), and the connection is fixed by the clamping bolt (126).

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